Designing and manufacturing vehicle floor trays

ABSTRACT

A vehicle floor tray is molded from a multiple extrusion polymer sheet such that it has high shear and tensile strength, an acceptable degree of stiffness and a high coefficient of friction on its upper surface. The floor tray design is digitally fitted to a foot well of a particular vehicle such that large areas of at least two upstanding walls of the tray depart from respective surfaces of the foot well by no more than an eighth of an inch.

RELATED APPLICATIONS

This application is a continuation of copending U.S. Nonprovisional application Ser. No. 11/463,203 filed on Aug. 8, 2006, which is in turn a division of U.S. Nonprovisional application Ser. No. 10/976,441 filed on Oct. 29, 2004, now U.S. Pat. No. 7,316,847. The disclosures and drawings of those applications are fully incorporated by reference herein.

BACKGROUND OF THE INVENTION

Motor vehicles are almost always operated in the out of doors and are frequently parked there. It is therefore very common for their occupants to have wet or muddy feet—if the occupants have not just finished an outdoor activity, at least they have had to walk across a possibly wet, snowy or muddy surface to access their vehicles. For decades, therefore, vehicle owners have been attempting to protect the enclosed interiors of their vehicles (cars, trucks, SUVs) from what they themselves track into them. The conventional solution to this has been to provide a vehicle floor mat which may be periodically removed by the owner and cleaned.

Human beings have a tendency to move their feet around, and foot motion is an absolute requirement in operating most vehicles. This has caused a problem, in that the occupants of a vehicle have a tendency to push around the floor mats with their feet. The floor mats end up not being centered on the area protected, or pushed up so as to occlude the gas, brake or clutch pedals, or bunched up or folded over—all undesirable conditions. One objective of floor mat manufacturers has therefore been to provide a floor mat that will stay put and which will not adversely affect vehicle operation.

The foot wells of cars, trucks and SUVs vary in size in shape from one model of vehicle to the next. Floor mat manufacturers have noticed that floor mats which at least approximately conform to the shape of the bottom surface of the foot well stay in place better and offer more protection. It is also common for such floor mats, where provided for front seat foot wells, to have portions which are meant to lie against the firewalls or front surfaces of the foot wells. Even as so extended it is not too hard to provide a floor mat of flexible material that will approximately conform to these two surfaces, as the designer only has to mark a two-dimensional periphery of the mat in providing one which will fit reasonably well.

More recently, vehicle floor trays have come onto the market. Most front-seat vehicle foot wells are actually three-dimensional concave shapes, typically with complex curved surfaces. Floor trays have sidewalls that offer enhanced protection to the surfaces surrounding the vehicle floor, as might be needed against wearers with very muddy or snowy shoes. Conventional vehicle floor trays try to fit into these three-dimensional cavities, but so far their fit to the surfaces that they are supposed to protect has been less than optimum. A conventional vehicle floor tray is typically molded of a single-ply rubber or plastic material, exhibits enough stiffness to retain a three-dimensional shape, but is also at least somewhat flexible. Fitting such a tray to the complex three-dimensional surface of a vehicle foot well has proven to be difficult, and the products currently in the marketplace have limited consumer acceptance because of their loose fit inside the foot well. There is often, and in many places, a considerable space between the exterior wall of these conventional trays and the interior surface of the foot well. This causes the wall to noticeably deform when the occupant's foot contacts it. Vehicle owners have a tendency to dislike floor trays which rattle, deform, shift and flop about. A need therefore persists for a floor tray that will have a more exact fit to the vehicle foot well for which it is provided, that stays in place once it is installed, and that provides a more solid and certain feel to the occupants' feet.

Some vehicle floor mats that are now on the market have fluid reservoirs built into them. Particularly in cold or wet climates, dirty water has a tendency to be shed onto the floor mat, where it persists until it evaporates. If there is enough of it, it will leak off of the floor mat and stain the carpeting of the foot well that the mat was meant to protect. These reservoirs typically are recessed areas in the mats that provide the mats with an enhanced ability to retain snow-melt and the like, until the water evaporates or can be disposed of by the vehicle owner or user. One advanced design places treads in the middle of the reservoir, such that the feet of the occupant are held above any fluid that the reservoir collects. But including such a reservoir within a floor tray that otherwise has an acceptable fit to the surface of a vehicle foot well has not yet been done, since there are problems in incorporating a three-dimensional liquid-holding vessel into a product that ideally conforms, on its lower surface, to the surface of the foot well. Further, a reservoir which collects drip water from a large surface, such as a vehicle floor tray, will exhibit more problems in keeping the collected fluid from sloshing about in a moving vehicle.

Conventional vehicle floor mats and trays are molded from a single rubber or plastic material. The selection of this material is controlled by its cost, its resistance to shear forces, its tensile strength, its abrasion resistance, its ability to conform to the surface of the vehicle foot well, its sound-deadening properties and how slippery or nonslippery it is relative to the occupants' feet, with nonslipperiness (having a relatively high coefficient of friction) being advantageous. Often the designer must make tradeoffs among these different design constraints in specifying the material from which the tray or mat is to be made.

SUMMARY OF THE INVENTION

According to one aspect of the invention, there is provided a vehicle floor cover, mat or tray which is removably installable by a consumer and which is formed of at least three layers that are bonded together, preferably by coextrusion. The three layers include a central layer whose composition is distinct from a bottom layer and a top layer. Preferably, all three layers are formed of thermoplastic polymer materials. In another aspect of the invention, the top layer exhibits a kinetic coefficient of friction with respect to a sample meant to emulate a typical shoe outsole (neoprene rubber, Shore A Durometer 60) of at least about 0.82.

Preferably, a major portion of the central layer is a polyolefin. More preferably, the polyolefin is either a polypropylene or a polyethylene. Most preferably, the polyolefin is high molecular weight polyethylene (HMPE) as herein defined. In an alternative embodiment, the central layer can be a styrene-acrylonitrile copolymer (SAN) or an acrylonitrile-butadiene-styrene (ABS) polymer blend.

Preferably, a major portion of the top layer is a thermoplastic elastomer, such as one of the proprietary compositions sold under the trademarks SANTOPRENE®, GEOLAST® and VYRAM®. VYRAM® is particularly preferred. In another embodiment, a major portion of the top layer can be an ABS polymer blend. Where ABS is used in both the top and central layers, it is preferred that the amount of the polybutadiene phase in the top layer be greater than the amount of this phase in the central layer.

It is further preferred that a major portion of the bottom layer likewise be a thermoplastic elastomer, and conveniently it can be, but does not have to be, of the same composition as the major portion of the top layer.

Preferably one or more of the layers is actually a polymer blend, in which a minor portion is preselected for its coextrusion compatibility with the adjacent layer(s). Thus, a minor portion of the top and bottom layers can consist of a polyolefin, while a minor portion of the central layer can consist of a thermoplastic elastomer. In each case, it is preferred that the minor portion be no more than about one part in four by weight of each layer, or a weight ratio of 1:3. Where all three layers are preselected to be ABS blends, the amount of polybutadiene preferably is decreased in the central layer relative to the top and bottom layers.

While the preferred embodiment of the vehicle floor cover consists of three integral layers, any one of the recited layers can in fact be made up of two or more sublayers, such that the total number of sublayers in the resultant mat or tray can exceed three.

In another embodiment, the thermoplastic elastomer constituent of the top, central and/or bottom layers described above can be replaced with a natural or synthetic rubber, including styrene butadiene rubber, butadiene rubber, acrylonitrile butadiene rubber (NBR) or ethylene propylene rubber (EPDM).

According to a related aspect of the invention, a vehicle floor cover is provided that has three layers bonded together, preferably by coextrusion. Major portions of the top and bottom layer consist of thermoplastic elastomer(s). The top and bottom layers have compositions distinct from the central layer, which can be chosen for its relatively low expense. It is preferred that a major portion of the central layer be a polyolefin and that major portions of the top and bottom layers be one or more thermoplastic elastomers. The polyolefin may be selected from the group consisting of polypropylene and polyethylene, and preferably is a high molecular weight polyethylene (HMPE). The thermoplastic elastomer can, for example, be SANTOPRENE®, GEOLAST® or VYRAM®, with VYRAM® being particularly preferred. It is also preferred that each of the layers be a polymer blend, with a minor portion of each layer being chosen for its coextrusion compatibility with adjacent layers. For example, the top and bottom layers can consist of a 3:1 weight ratio of VYRAM®/HMPE, and the central layer of a 3:1 weight ratio of HMPE/VYRAM®.

In an embodiment alternative to the one above, the top and bottom layers can consist of ABS polymer blends and the central layer can consist of SAN or an ABS in which the polybutadiene phase is present in a smaller concentration than in the top and bottom layers.

In yet another embodiment, the thermoplastic elastomer recited in this aspect of the invention may be replaced with a natural or synthetic rubber, such as styrene butadiene rubber (SBR), butadiene rubber, acrylonitrile butadiene rubber (NBR) or ethylene propylene rubber (EPDM).

In a further aspect of the invention, a vehicle floor tray or mat according to the invention is made of three layers, wherein a top layer and a bottom layer have composition(s) distinct from the central layer, and wherein at least one of the shear strength per cross-sectional area, tensile strength per cross-sectional area and stiffness per cross-sectional area is greater than any one of the layers from which the tray or mat is composed. It has been found that a triextruded vehicle mat or floor tray according to the invention exhibits a tensile strength at yield, a tensile stress at break, a tensile modulus, a shear strength and a flexural modulus (stiffness) which are superior to either a polyolefin-dominated single extrusion or a thermoplastic elastomer-dominated single extrusion. The triextrusion tray demonstrates these enhanced physical properties while at the same time affording an enhanced coefficient of friction to the feet of the occupant and improved tactile properties. By presenting such a surface to the shoe of the driver or passenger, the footing of the driver or passenger will be more sure and comfortable.

In a further aspect of the invention, a vehicle foot well tray is provided as a part of a system that has the vehicle foot well as its other main component. The tray has a greatly enhanced conformance to the surface of the vehicle foot well for which it is provided. At least two upstanding walls of the tray, both extending from the tray floor to a top margin, conform to respective surfaces of the vehicle foot well such that at least within that one-third of the area of the outer surface of these upstanding walls of the tray which is adjacent the top margin, 90% of that top third area departs by no more than about one-eighth of an inch from the foot well surfaces to which they mate. These upstanding tray surfaces may be opposed surfaces or adjacent surfaces, and preferably are both. In a preferred embodiment, the tray departs from a door sill surface of the vehicle foot well, and/or a sill curve of the vehicle foot well, by about 0.025 inches. The upstanding sidewalls of the floor tray conform to the foot well surfaces which they cover, even where such foot well surfaces present both concave and convex surface elements.

In a still further aspect of the invention, a top margin of a vehicle floor tray is substantially coplanar on at least two upstanding sidewalls thereof. Preferably, the top margin of the tray is substantially coplanar through three or even four continuous upstanding sidewalls. This eases the design of the floor tray, increases hoop strength and assures that all upstanding surfaces of the vehicle foot well will receive adequate protection from muddy footwear. In a particularly preferred embodiment, the plane of the top margin is forwardly and upwardly tilted relative to a horizontal floor. This provides enhanced protection to the vehicle foot well precisely in the place where muddy footwear are likely to be, near the accelerator, brake and clutch pedals or the firewall. In a preferred embodiment, the tray is at least five inches deep at its deepest part.

In a further aspect of the invention, the above mentioned tight tolerances are made possible by a novel vehicle floor tray manufacturing method. In a first step according to the invention, points on a surface of the vehicle foot well are digitally measured with a coordinate measuring machine (CMM). These points are stored in a computer memory. A foot well surface is generated which includes these points, preferably by connecting linear groups of the points together by using B-splines, and lofting between the B-splines to create areal portions of the foot well surface. Using this typically complex three-dimensional, predominately concave surface, which may have several concavely and convexly curved portions, a corresponding substantially convex outer floor tray surface is built up such that in many regions, the distance between the outer surface of the tray and the surface of the foot well is no more than about one eighth of an inch, insuring a snug fit.

In one embodiment of the invention, a reservoir is incorporated into the tray floor as a collection and evaporation area for drip water from the feet and legs of the occupant. Combination baffles/treads are provided in the reservoir to impede lateral movement of the collected fluid. Longitudinal and transverse portions of these baffles are joined together. Channels are cut into another portion of the central area of the tray to direct fluid to the reservoir, such that the bottom of the channels is beneath a general tray floor surface but above the bottom of the reservoir. In a preferred driver's side embodiment, the channels are omitted from a portion of the floor tray upper surface to leave a blank space where the driver's heel will rest when operating the gas and brake pedals.

BRIEF DESCRIPTION OF THE DRAWINGS

Further aspects of the invention and their advantages can be discerned in the following detailed description, in which like characters denote like parts and in which:

FIG. 1 is an isometric view of one embodiment of a vehicle floor tray according to the invention;

FIG. 2 is a top view of the floor tray illustrated in FIG. 1;

FIG. 3 is an isometric and transverse sectional view of the floor tray seen in FIGS. 1 and 2, the section taken substantially along line 3-3 of FIG. 2;

FIG. 4 is an isometric and longitudinal sectional view of the floor tray shown in FIGS. 1 and 2, the section taken substantially along line 4-4 of FIG. 2;

FIG. 5 is a side view of the tray illustrated in FIG. 1, taken from the outer side;

FIG. 6 is a highly magnified sectional view of a vehicle floor tray, showing triextruded layers;

FIG. 7 is a schematic block diagram showing steps in a design and manufacturing process according to the invention; and

FIG. 8 is an isometric and schematic view of a digitally acquired vehicle foot well floor surface from which the illustrated floor tray was made;

FIG. 9 is a partly transverse sectional, partly isometric view of both the floor tray illustrated in FIG. 2 and the vehicle foot well surface illustrated in FIG. 8, taken substantially along line 9-9 of FIG. 2 and substantially along line 9-9 of FIG. 8;

FIG. 10 is a partly transverse sectional, partly isometric view of both the floor tray illustrated in FIG. 2 and the vehicle foot well surface illustrated in FIG. 8, taken substantially along line 10-10 of FIG. 2 and substantially along line 10-10 of FIG. 8;

FIG. 11 is a detail of a firewall region of FIG. 10;

FIG. 12 is a detail of a seat pedestal region of FIG. 10;

FIG. 13 is a partly longitudinal sectional, partly isometric view of both the floor tray illustrated in FIG. 2 and the vehicle foot well surface illustrated in FIG. 8, taken substantially along line 13-13 of FIG. 2 and substantially along line 13-13 of FIG. 8; and

FIG. 14 is a detail of a kick plate region of FIG. 13.

DETAILED DESCRIPTION

An isometric view of one commercial embodiment is shown in FIG. 1. The illustrated vehicle floor tray indicated generally at 100 is preferably molded from a blank, in sheet form, of water-impervious thermoplastic polymer material having a uniform thickness, although the present invention could be fabricated from another process such as injection molding. The floor tray 100 is preferably formed of a triextruded thermoplastic material such that the properties of a central or core layer can be different than the properties of the external or jacket layers, and such that the triextrusion is tougher and stiffer per unit thickness than any of the layers from which it is made, as will be described in more detail below.

The vehicle floor tray or cover 100 is meant to protect both the floor and at least the lower sides of a vehicle foot well, and thus takes on a much more three-dimensional shape than is typical of prior art floor mats. The floor tray 100 includes a floor or central panel 102, which in the illustrated embodiment includes a plurality of fore-to-aft or longitudinal parallel straight channels 104 that are disposed in a forward region 106 of the floor panel 102. Preferably these channels are about an eighth of an inch deep so that they will correctly channel runoff, and can be about one-quarter of an inch wide. In FIG. 1, forward is a direction to the upper left, while rearward is the direction to the lower right, and the terms are used in conformance with the orientation of the vehicle in which the tray is designed to be placed. As used herein, “longitudinal” means for-and-aft or along the axis of vehicle travel, while “transverse” means at a ninety degree angle to such an axis, or side-to-side.

A rearward or back region 108 of the floor panel 102 is largely occupied by a reservoir 110, whose bottom is made up by a substantially planar general surface 112. General surface 112 is situated to be below a general surface 114 of the forward region 106. Preferably, the general bottom reservoir surface 112 is also below the bottommost points of the respective channels 104, as by about one-eighth of an inch, so that fluid in the channels 104 will empty into the reservoir 110.

The channels 104 are designed to channel liquid runoff from the user's feet or footwear to the reservoir 110. In many vehicles, the portion of the vehicle floor (not shown in this Figure; see FIGS. 8-11) which underlies the forward region 106 slopes from front to rear, and thus the tray 100, by simply conforming to the contour of the underlying vehicle floor portion, will channel fluid to the reservoir. For those vehicle designs in which the underlying vehicle floor is not pitched in this manner, the tray 100 can advantageously be designed to create this fluid flow, as by making the material thicker in portion 106 than in portion 108, or by giving the bottoms of channels 104 a front-to-rear slope.

The channels 104 occupy most of the forward region 106, although in this and other commercial embodiments a space 116 on the forward right hand side has been left open to receive the foot of the driver that operates the accelerator and brake pedals. In the illustrated embodiment, this space or clear area 116 is a delimited by a 180 degree arc of a circle of about four inch radius (shown in dashed line). The clear area 116 is provided so that the relatively deep channels 104 do not catch the heel of the driver's shoe. In other embodiments, the clear area 116 can take other shapes or positions, so long as the heels of almost all drivers, while operating the brake and accelerator pedals of the vehicle for which the particular tray is designed, will rest within its confines.

The reservoir 110 has interspersed within it a plurality of tread surfaces or upstanding, hollow elongate baffles 118, which have two purposes. The first purpose is to elevate the shoe or foot of the occupant above any fluid which may have collected in the reservoir 110. The second purpose is to prevent this accumulated fluid from sloshing around. To this end, most of the tread surfaces/baffles 118 have both fore-to-aft or longitudinal portions 120 and side-to-side or transverse portions 122. This prevents large fluid movement in a forward or rearward direction, as would otherwise happen during acceleration or braking of the vehicle, and also large fluid movement side-to-side, as when the vehicle is turning. Preferably, each or at least most of the fore-to-aft portions 120 are joined to respective side-to-side portions. This further compartmentalizes and restricts the movement of collected fluid. Fluid in one portion of the reservoir 110 may make its way only slowly and through a complicated path to another distant portion of the reservoir 110, through channels 124 around the ends of the treads or baffles 118. The reservoir design thus creates a large surface area which promotes evaporation of the fluid, while at the same time restricts fluid movement prior to such evaporation.

Disposed around the central or floor panel 102 are a series of upstanding side panels, which will vary in number and configuration from one vehicle model to the next. In the illustrated embodiment these upstanding panels include a back panel 130 that is disposed adjacent the bottom of a vehicle front seat, or a vehicle pedestal for receiving same; an inner side panel 132 that closely fits a transmission tunnel or “hump” in this vehicle; a forward panel 134 that closely conforms to a vehicle firewall; and an outer side panel 136. In most embodiments, the outer side panel or kick plate panel 136 will only extend from its transition with panel 134 to a corner 138, at which point there begins a door sill curve 208 which transitions into a door sill panel 140. Unlike the other panels, the sill panel 140 is not generally upstanding but instead conforms to the sill of a vehicle door and lies in a substantially horizontal plane. In this way occupant ingress and egress is not occluded. In many embodiments, including the illustrated embodiment, the sill panel 140 is at an elevation below that of the general surface 114 of the floor forward region 106 and even below the general surface (bottom) 112 of the reservoir 110. Very large amounts of fluid (in excess of the reservoir capacity) may therefore flow right out of the vehicle without having the opportunity to damage the vehicle interior. It should be noted that in these FIGUREs, the lines dividing the panels are conceptual only and do not appear in the final part. As will be described in further detail below, the tray 100 preferably is integrally molded as a one-piece construction.

In one important aspect of the invention, the tray 100 is closely fitted to the vehicle foot well in which it is designed to be placed. Panels 130, 132, 134, 136 and 140 are all formed so as to as closely conform to the vehicle surfaces against which they are positioned, to an extent not found in prior art vehicle floor trays. In a preferred embodiment, at least throughout the top one-third of the areas of these panels that is adjacent a vehicle tray top margin 150, at least ninety percent of the points on the outer surface of the peripheral or side panels 130-136 are no more than about one-eighth of an inch from the corresponding points on the surfaces that they are formed to mate with. This close conformance occurs even where the underlying vehicular surface is complexly curved or angled. Certain portions of the vehicle foot well surface, such as kick plate transition plate 214, can have both convexly and concavely curved elements. The preferred tolerance of door sill curve 208 and sill plate 140 is even tighter, about 0.025 in.

The close conformance of the tray side panels to respective surfaces of the vehicle foot well produces a protective tray which will not be horizontally displaced under lateral forces created by the occupant's feet, or by the motion of the vehicle. Opposing pairs of the peripheral panels “nest” or “cage” the tray 100, preventing its lateral movement. Thus, outer side panel or kick plate panel 136, which closely conforms to a vehicle side wall at that position, has as its counterpart a portion 142 of the inner side panel 132. Any tendency of the tray 100 to shift leftward is stopped by panel 136; any tendency of the tray 100 to shift rightward is stopped by panel portion 142. In a similar manner, the upstanding rearward and forward panels 130 and 134 cooperate to “cage” any forward or rearward motion of the tray 100 within the vehicle foot well.

The close conformance of the outer or lower surfaces of panels 130-136, 218, 140 to their respective mating surfaces of the vehicle foot well also increases the frictional force which will oppose any lateral movement. The result of this close conformance is to provide a floor tray which will not undesirably shift position, and which will provide a steady and sure rest to the feet of the occupants.

In most commercial embodiments of the vehicle floor tray 100, the side panels 130-136, 140 will not be formed to abruptly extend from the bottom panel 102, but rather will be joined to the bottom or central panel 102 through transitions. These transitions may be sloped or curved and will have a varying degree of gradualness. According to the invention, the transitions between the outer and bottom surfaces of the tray 100 conform wherever possible to underlying surfaces of the vehicle foot adjacent these transitions.

In FIG. 2, for example, there is seen a large transition or subpanel 200 which extends from forward portion 106. A further subpanel 202 joins transitional subpanel 202 to the forward sidewall 134. Inner or transmission tunnel sidewall 132 is joined to the pan 102 through a curved transitional fillet 204. The rear upstanding panel 130 is joined to the rear portion of bottom panel 102 through a small transition 206. A transition or sill curve 208 between the outer sidewall 136 and the sill panel 140 takes the form of a gradual curved surface.

The present invention also employs (typically) curved transitions between adjacent side panels. For example, a curved transition 210 joins the back panel 130 to the inner side panel 132. A curved transition 212 joins the transmission tunnel or inner side panel 132 to the front or firewall panel 134. A transition 214, which in this embodiment takes the shape of an S-curve and conforms to a portion of vehicle wheel well, joins the front panel 134 to the outer side panel 136. The close conformance (preferably to a tolerance of about ⅛ in.) wherever possible to the transitions of the vehicle foot well surface by the outer surface of the tray 100 enhances a close fit.

In the illustrated embodiment, the tray according to the invention has been made by placing a sheet of substantially uniformly thick triextruded thermoplastic material into a mold and heating the mold. When this process is used, discrete layers having different characteristics can persist into the final product, as will be described in more detail below. On the other hand, as using this manufacturing process it is difficult to provide the channels and reservoir structure according to one aspect of the invention while closely conforming the bottom surface 300 (FIGS. 3 and 4) to a mating surface of the vehicle foot well. In this central area, and according to the preferred manufacturing process, a departure away from ⅛ in. tolerance must be made in order to obtain the above-described benefits of fluid flow and retention. But because the side panels 130-136, 140 and their associated transitions continue to closely conform to most of the remaining vehicle foot well surfaces, the tray 100 continues to be locked in one place.

FIGS. 10-14 superimpose a floor tray 100 on a surface 802 of a vehicle foot well for which the tray is designed according to the invention. In the part-isometric, part-longitudinal sectional view seen in FIG. 10, It can be seen that on the section taken there is a quite tight conformance of the lower surface 300 of the tray 100 to the modeled surface 802 of the vehicle foot well. As best seen in FIG. 11, the outer surface of the firewall sidewall 134 stays within one-eighth of an inch of the firewall surface 826 for at least three-quarters of the length of surface 826 as measured from the top margin 150 of the tray. In areas 1000, 1002 and 1004 (FIG. 10), the modeled surface 802 of the vehicle foot well is actually above or to the interior to the tray 100. This negative interference is tolerable and in some instances is even desirable because the surface 802 is that of a vehicle carpet, which can or even should be depressed upon the installation of the tray 100 into the vehicle foot well. Such a tight fit is particularly desirable, for example, in the region of the tray around the accelerator pedal.

FIG. 12 is a detail of FIG. 10 in the area of the seat pedestal and a portion of the reservoir 110. Once again, there is a very tight conformance of the outer surface of the back panel 130 to the modeled seat pedestal surface 828 throughout most of its length on this section, well within ⅛ inch.

FIG. 13 shows a side-to-side or transverse section taken in a relatively forward location, so as to cut through the kick plate tray and foot well surfaces 136, 830 on one side and the tray and foot well transmission tunnel surfaces 132, 810 on the other. As can be seen, tolerance to within ⅛ of an inch is maintained at least for the upper one-third of the surface area of these mating surfaces. Areas 1000, 1002 (partially represented in FIG. 13) and 1006 are areas of negative standoff or interference in which the modeled surface 802 of the vehicle foot well is positioned interiorly of the vehicle tray 100. As above explained, this mismatch is permissible if held to ⅛ inch or less, and is even desirable in some points, because the surface 802 is an image of vehicle carpeting rather than a hard surface.

In FIG. 14, there is seen at 1400 an intentional increase of radius of the transition between kick plate panel 136 and bottom wall 102. This is done because, for the model shown, the foot well kick plate surface 830 is both vertical and is relatively deep. Therefore, sidewall 136 needs to have a draft of at least two degrees (and more preferably five degrees) relative to the surface 830 to insure that the wall of the tray 100 will remain acceptably thick enough at the junction of walls 136, 102. The increase of the radius 1400 accomplishes this. Nonetheless, even on this section the outer surface of the kick plate 136 stays within one-eighth of an inch of the kick plate surface 830 for at least one-third of the length, as measured from margin 150.

More generally, at least ninety percent of that top one-third of the surface area of each sidewall 130-136 that is adjacent the top margin 150 stays within ⅛ in. of the vehicle foot well surfaces with which they are designed to mate. Alternatively, ninety percent of the top one-half of the outer surface area of all upstanding sidewalls is within this ⅛ inch tolerance of respective foot well surfaces. In even a further alternative measurement of tolerance, it is preferred that at least fifty percent of the outer area of the upstanding sidewalls 130-136 be within ⅛ inch of the vehicle foot wells to which they correspond, regardless of position relative to the top margin 150.

As best seen in FIGS. 1, 5 and 10, a top margin 150 of the tray 100, which terminates all of the upstanding sidewalls 130, 132, 134, 136 and 138, substantially lies in a single plane which is tilted forwardly upwardly relative to the horizontal plane. The continuous nature of the top margin 150 means that the produced tray 100 has a higher hoop strength, and better protects the vehicle carpeting from dirt or mud on the sides of the occupant's feet. The occupant's feet tend to occupy positions on the forward region 106, but the position of the top margin 150 around this region is high, being at least five inches removed from the floor of the tray at its greatest separation.

Composition

According to one aspect of the invention, it is preferred that the tray or cover 100 not be of uniform composition throughout, but rather be a laminate having at least three layers which are bonded together. A preferred composition of the tray 100 is shown in the highly magnified sectional detail shown in FIG. 6. In this illustrated embodiment, the tray 100 consists of a top layer 600, a central or core layer 602, and a bottom layer 604. All three layers 600-604 preferably consist of one or more water-impervious thermoplastic polymers, but layers 600 and 604 have properties which are at least different from core layer 602 and may even have properties which are different from each other. The trilayer cover is shown to be a three-dimensional floor tray in the drawings, but can also be a more two-dimensional floor mat of more limited coverage. Top layer 600 is made from a material selected for its tactile properties, its relatively high static and dynamic coefficients of friction with respect to typical footwear, and its resistance to chemical attack from road salt and other substances into which it may come into contact. Top layer 600 preferably includes a major portion of a thermoplastic elastomer such as VYRAM®, SANTOPRENE® or GEOLAST®, which are proprietary compositions available from Advanced Elastomer Systems. VYRAM® is preferred, particularly Grade 101-75 (indicating a Shore A hardness of 75). An upper surface 606 of the top layer 600 may be textured by a “haircell” pattern or the like so as to provide a pleasing tactile feel and visual appearance, as may a lower surface of the bottom layer 604.

It is preferred that top layer 600 be a polymer blend, in which instance a minor portion of the composition of the top layer 600 is selected for its coextrusion compatibility with core layer 602. A polyolefin polymer is preferred, such as polypropylene or more preferably polyethylene, even more particularly a high molecular weight polyethylene (HMPE). As used herein, HMPE is a commodity product, available from many sources, and distinguished in the industry from low density polyethylene (LDPE) and high density polyethylene (HDPE) by its approximate properties:

Characteristic LDPE HDPE HMPE Specific Gravity, 0.918 0.96 0.95 ASTM D-792 Tensile Modulus, 22,500 95,000 125,000 ASTM D-638, psi Tensile Strength 1,800 4,500 3,600-3,700 @ Yield, ASTM D-638, psi Flexural Modulus, 225,000 165,000-175,000 ASTM D-790, psi Hardness, 45 66 68 ASTM D-2240, Shore D

In the above table, the testing methods by which the properties are determined are given for the purpose of reproducibility.

Particularly where the thermoplastic elastomer and the polyolefin are respectively selected as VYRAM® and HMPE, the proportion by weight of the thermoplastic elastomer to polyolefin material in layer 600 is preferably selected to be about 3:1. It has been discovered that some polyolefin material needs to be present in layer 600 for coextrusion compatibility with central layer 602, in the instance where a major portion of the layer 602 is also a polyolefin.

In an alternative embodiment, the thermoplastic elastomer component of the top layer 600 may be replaced with an elastomer such as natural rubber, acryl-nitrile butadiene rubber (NBR), styrene butadiene rubber (SBR), or ethylene propylene diene rubber (EPDM).

In a further alternative embodiment, layer 600 can be an acrylonitrile butadiene styrene (ABS) blend. ABS is a material in which submicroscopic particles of polybutadiene are dispersed in a phase of styrene acrylonitrile (SAN) copolymer. For layer 600, the percentage by weight of polybutadiene, which lends elastomeric properties to the material, should be chosen as relatively high.

The core or central layer 602 preferably is composed of a thermoplastic polymer material that is selected for its toughness, stiffness and inexpensiveness rather than its tactile or frictional properties. Preferably a major portion of it is a polyolefin such as polypropylene or polyethylene. More preferably, a major portion of the layer 602 is composed of HMPE as that material has been defined above.

It is preferred that the central layer 602 be a blend, and in that instance a minor portion of layer 602 is composed of a material selected for its coextrusion compatibility with top layer 600 (and bottom layer 604 described below). In the illustrated embodiment, this minor portion is a thermoplastic elastomer such as SANTOPRENE®, GEOLAST® or VYRAM®. VYRAM® Grade 101-75 is particularly preferred. For layer 602, and particularly where the polyolefin and the thermoplastic elastomer are respectively selected as HMPE and VYRAM®, the proportion by weight of polyolefin to thermoplastic elastomer is preferred to be about 3:1. More generally, the percentages of the minor portions in layers 600 and 602 (and layer 604) are selected as being the minimum necessary for good coextrusion compatibility.

In an alternative embodiment, where layer 600 has been chosen as a polybutadiene-rich layer of ABS, layer 602 is chosen as a grade of ABS having less of a percentage by weight of polybutadiene in it, or none at all (effectively, styrene acrylonitrile copolymer or SAN).

Bottom layer 604 has a lower surface 300 which will be adjacent the vehicle foot well top surface. Typically, this surface is carpeted. The bottom layer 604 is a thermoplastic polymer material selected for its wear characteristics, as well as its sound-deadening qualities and a yieldability that allows the layer 604 to better grip “hard points” in the vehicle foot well surface as well as conform to foot well surface irregularities. Preferably, a major portion of the layer 604 is composed of a thermoplastic elastomer, such as SANTOPRENE®, GEOLAST® or, preferably, VYRAM®. VYRAM® Grade 101-75 is particularly preferred.

It is preferred that the bottom layer 604 be a polymer blend. In this instance, a minor portion of the bottom layer 604 is selected for its coextrusion compatibility with the core layer 602. Where core layer 602 is mostly made of a polyolefin material, it is preferred that a polyolefin be used as the minor portion of the bottom layer 604. This polyolefin can be, for example, polypropylene or polyethylene, and preferably is HMPE. The amount of the minor portion is selected to be that minimum amount that assures good coextrusion compatibility. Where the polyolefin and the thermoplastic elastomer are respectively chosen to be HMPE and VYRAM®, it has been found that the thermoplastic elastomer: polyolefin ratio by weight in the layer 604 should be about 3:1.

In an alternative embodiment, the thermoplastic elastomer component of layer 604 may be replaced with a rubber, such as natural rubber, NBR, SBR or EPDM.

In another alternative embodiment, where the central layer 602 has been selected as ABS or SAN, layer 604 can be selected as a grade of ABS which has a higher percentage by weight of polybutadiene in it than in central layer 602.

Bottom jacketing layer 604 conveniently can have the same composition as top jacketing layer 600, but the two jacketing layers do not have to be similar. What is important that, where the tray 100 is to be formed as a triextrusion (as is preferred), layers 600, 602 and 604 be sufficiently compatible that they can be triextruded as a single sheet.

It is preferred that most of the thickness of the tray 100 be made up by the core layer 602, which is used as the principal structural component of the tray 100. The core layer 602 has at least minimally acceptable tensile strength, shear strength and high flexural modulus, while at the same time being significantly less expensive than the thermoplastic elastomer-dominated jacketing layers. The jacketing layers 600 and 604 are selected to present good wear surfaces and to have a good resistance to chemical attack from substances such as road salt. Top layer 600 is selected to exhibit a relatively high coefficient of friction with respect to typical occupant footwear. The composition of bottom layer 604 is selected for its sound-deadening and yieldability qualities.

The total thickness of tray 100 is the sum of dimensions a, b and c. In the illustrated embodiment, jacketing layer thicknesses a and c are each about 12.5% of the total thickness, while core layer thickness b is about 75%. In one embodiment, the total thickness of the tray 100 (or, more precisely, of the blank sheet used to mold the tray 100) is approximately 0.120 inch. Of this, core layer 602 is about 0.09 inch, while jacketing layers 600 and 604 are each about 0.0150 inch. In an alternative embodiment, the layer 600 can be made to be appreciably thicker than layer 604, as top surface 606 is a wear surface for the shoes of the occupant and will see more abrasive dirt and more wear than surface 300 in typical applications. In another alternative embodiment, the thickness of layer 604 may be increased, allowing it to even better conform to the vehicle foot well surface with which it is designed to mate and to increase sound-deadening.

A preferred embodiment of the present invention combines the high coefficient of friction, tactile qualities, sound-deadening and yieldability obtainable with a thermoplastic elastomer with the modest cost of a polyolefin. To demonstrate the technical advantages of a triextrusion tray over monoextruded prior art structures, tests measuring tensile strength, shear strength, flexural modulus and coefficient of friction were performed on (1) a triextrusion sheet material made and used according to the invention, (2) a monoextruded sheet of 75 wt. pct. VYRAM®/25 wt. pct. HMPE, and (3) a monoextruded sheet of wt. pct. VYRAM®/75 wt. pct. HMPE. The particular tests and their results are described below.

The first two tests performed concern static and dynamic coefficients of friction.

Example 1

These tests determined static and kinetic coefficients of friction of a sheet of triextrusion material with respect to an object meant to emulate an typical occupant shoe outsole. This “shoe” was composed of Shore A Durometer 60 neoprene rubber, formed as a “sled” measuring 2.5 in.×2.5 in.×0.238 in. The “shoes” were drawn across an upper, textured surface of a 0.120 in. triextrusion sheet formed according to a preferred embodiment of the invention measuring 4 in.×12 in. according to the procedure set forth in ASTM D 1894-01. The triextrusion sheet had, as its top layer, a blend of 75 wt. pct. VYRAM® Grade 101-75/25 wt. pct. HMPE. The core layer was 75 wt. pct. HMPE/25 wt. pct. VYRAM® Grade 101-75. The bottom layer was a blend of 25 wt. pct. HMPE/75 wt. pct. VYRAM® Grade 101-75. The bottom and top layers each comprised about 12.5% of the sheet thickness while the middle core layer comprised about 75% of the sheet thickness. Results are tabulated as follows.

Static Kinetic Test Static Sled Coefficient Kinetic Sled Coefficient Number Load (g) Weight (g) of Friction Load (g) Weight (g) of Friction 1 166 199.9 0.830 189 199.9 0.945 2 155 199.9 0.775 166 199.9 0.830 3 171 200.0 0.855 179 200.0 0.895 4 145 199.9 0.725 160 199.9 0.800 5 150 199.9 0.750 163 199.9 0.815 Average 0.787 0.857 Std. Dev. 0.054 0.061

Example 2

Five neoprene rubber “sleds” fabricated as above were drawn across a 4 in.×12 in. sheet of a single-extrusion 75 wt. pct. HMPE/25 wt. pct. VYRAM® Grade 101-75, according to ASTM D 1894-01. Results are tabulated below.

Static Kinetic Test Static Sled Coefficient Kinetic Sled Coefficient Number Load (g) Weight (g) of Friction Load (g) Weight (g) of Friction 1 157 200.1 0.785 162 200.1 0.810 2 151 200.0 0.755 148 200.0 0.740 3 163 200.1 0.815 170 200.0 0.850 4 146 200.1 0.730 148 200.1 0.740 5 154 200.1 0.770 155 200.1 0.775 Average 0.771 0.783 Std. Dev. 0.032 0.047

The above tests show that with respect to a typical shoe sole composition, a material consisting mostly of a thermoplastic elastomer like VYRAM® exhibits a higher coefficient of friction than a material consisting mostly of a high molecular weight polyolefin.

Example 3

These tests compared the tensile strength of a sheet of triextruded material as above described with a sheet of single-extruded blend of material consisting of 75 wt. pct. VYRAM®, Grade 101-75, and 25 wt. pct. HMPE, and further with a sheet of a single-extruded blend of material of 75 wt. pct. HMPE and 25 wt. pct. VYRAM® Grade 101-75. The tested single-extruded VYRAM®-dominated sheet was approximately 0.070 in. thick, while the HMPE-dominated sheet was approximately 0.137 in. thick. The triextrusion sheet was about 0.120 in. thick. The triextrusion sheet, the single-extruded VYRAM®-dominated sheet and the single-extruded HMPE-dominated sheet were die-cut into samples having an average width of 0.250″. The test performed was according to the ASTM D 638-03 testing standard. A cross-head speed of 20 in./min. was used. The extensiometer was set at 1000% based on 1.0″ gauge length. Samples were conditioned at 40 hours at 23 Celsius and 50% relative humidity prior to testing at these conditions. Test results are tabulated below.

Tensile Tensile Tensile Strength Stress Modulus Test at Yield Elongation at Break Elongation (Youngs) Number (psi) at Yield (%) (psi) at Break (%) (psi) Tri- 1 1680 24 1530 730 30800 Extrusion 2 1710 21 1610 710 30100 3 1700 21 1620 730 32200 4 1740 19 1660 770 32700 5 1690 17 1630 700 24400 Average 1700 20 1610 730 30000 Std. Dev. 23 3 48 27 3320 75% Vyram/ 1 1040 53 1400 620 15900 25% HMPE 2 1010 45 1430 630 17100 3 1050 98 1390 640 17100 4 1010 62 1430 620 16700 5 1030 88 1420 610 17100 Average 1030 69 1410 620 16800 Std. Dev. 18 23 18 11 522 75% HMPE/ 1 919 63 1130 630 30200 25% Vyram 2 914 61 1110 630 34100 3 925 69 1120 650 29500 4 910 67 1110 650 21500 5 912 68 1140 700 24000 Average 916 66 1120 650 27900 Std. Dev. 6 3 13 29 5060

The above data demonstrate that a triextrusion material according to the invention exhibits markedly greater tensile strength than a thermoplastic elastomer-dominated single-extrusion material. Also of interest is that the three-layer laminate exhibited a higher strength at yield and stress at break than the HMPE-dominated material, while showing a comparable tensile Young's modulus.

Example 4

Tests were performed on the above three materials for shear strength according to Test Standard ASTM D732-02. In these tests, a 1.00 in. dia. punch was applied to a 2.0 inch square of material until shear was achieved. The crosshead moved at 0.05 in/min. The test samples were preconditioned for at least 40 hours at 23 Celsius and 50% relative humidity, which were the conditions under which the tests were performed. Test results are tabulated below.

Thickness Shear Force Shear Sample Name Test Number (in.) (lbf) Strength (psi) Tri-Extrusion 1 0.119 747 2000 2 0.122 783 2040 3 0.119 747 2000 4 0.121 757 1990 5 0.117 734 2000 Average 754 2010 Std. Dev. 18 19 75% VYRAM/ 1 0.072 423 1870 25% HMPE 2 0.070 416 1890 3 0.073 489 2130 4 0.072 481 2130 5 0.073 455 1980 Average 453 2000 Std. Dev. 33 126 75% HMPE/ 1 0.135 680 1600 25% VYRAM 2 0.137 688 1600 3 0.134 687 1630 4 0.136 724 1690 5 0.137 687 1600 Average 693 1620 Std. Dev. 18 39

The above test data show that, as normalized for the different thicknesses tested, the triextrusion material is similar in shear strength to the 75% VYRAM/25% HMPE single-extrusion blend, and superior in shear strength to the 75% HMPE/25% VYRAM® single-extrusion blend.

Example 5

Tests were performed to determine the flexural properties of samples of a tri-extrusion material of the above-described formulation, a 75 wt. pct. VYRAM/25 wt. pct. HMPE material, and a 75 wt. pct. HMPE/25 wt. pct. VYRAM material (in all tests. the thermoplastic elastomer used was VYRAM® Grade 101-75). The tests were performed according to the ASTM D790-03 test method, Method I, Procedure A. For the tri-extrusion the dimensions of the samples averaged 0.490″×0.0119″×5.00″, the span length was 1.904 in., and the cross-head speed was 0.051 in./min. For the 75% VYRAM/25% HMPE material, the dimensions of the samples averaged 0.484″×0.072″×5.00″, the span length was 1.152 in., and the cross-head speed was 0.031 in./min. For the 75% HMPE/25% VYRAM material, the dimensions of the samples averaged 0.50″×0.138″×5.00″, the span length was 2.208 in., and the cross-head speed was 0.059 in/min. In all tests, the span-to-depth ratio was 16+/−1:1, the radius of the supports was 0.197 in., and the radius of the loading nose was 0.197 in. The tests were performed at 23 Celsius and 50% relative humidity and the samples conditioned for 40 hours at this temperature and humidity before the tests were performed. Results are tabulated below.

Flexural Stress At Flexural Modulus Sample Test 5% Deflection (tangent*) Name Number (psi) (psi) Triextrusion 1 294 33400 2 317 36000 3 304 33500 4 318 35700 5 305 33200 Average 308 34400 Std. Dev. 75% Vyram/ 1 234 15400 25% HMPE 2 238 16400 3 230 14500 4 225 14300 5 228 14300 Average 231 15000 Std. Dev. 5 915 75% HMPE/ 1 508 13000 25% Vyram 2 505 13800 3 496 13100 4 497 12900 5 518 13800 Average 505 13300 Std. Dev. 9 444

The asterisk in the table indicates that the reported values were arrived at by computer generated curve fit. These data show that the triextrusion is significantly stiffer than either monoextruded sheet. Overall, the triextrusion demonstrates superior properties in terms of tensile strength, shear strength and stiffness per unit cross-sectional area in comparison with that of any of the layers of materials from which the laminate is made, demonstrating that a triextruded tray or mat will be tougher and stiffer than one made of either monoextruded blend by itself.

Process

FIGS. 7 and 8 provide an overview of a process for making the vehicle floor trays or covers according to the invention. The vehicle floor trays and covers are custom-fabricated for discrete vehicle models. At step 700, points on the vehicle foot well for which the floor tray is to be manufactured are digitally measured and captured. Preferably this step uses a coordinate measuring machine (CMM) which records each of a large plurality of points on the surface of the vehicle foot well to which the floor tray is to be fitted. The inventor has found that a FARO® Arm has been efficacious in obtaining these data using a contact method. It has been found that laying out points in linear groups, as by marking the locations to be measured on tape prior to measurement, is efficacious in capturing enough data points to later recreate the surface of which they are a part.

The data thus collected are stored in a file. The points of surface data are spaced from each other as a function of the complexity of the surface on which they reside. Few points of data are needed to establish large surface planes. More points of data are used in defining curved surfaces, with the density of data points varying according to the sharpness of the curve. In FIG. 8, representative ones of these points are shown by small “x”s at 800, on a surface 802 that is reconstituted using the technique described immediately below. A typical data file will contain about a thousand points, spread over an imaged foot well surface area of about ten square feet.

The CMM data file is imported into a CAD program, which is used by a designer to reconstitute a vehicle foot well surface from the captured points. First, at step 701 different “lines” of these points are connected together by B-splines 804. The splines 804, which the CAD program can automatically generate, are used to estimate all of the points on the line other than the captured data points of that line. The splines 804 are separated apart from each other as a function of the topographical complexity of the portion of the surface that they cover. For large flat areas, such as sill plate 806, the splines 804 may be separated far apart, as a plane between the splines is a good estimate of the surface in that area. For complex or tightly curved areas, such as sill curve 832 or kick plate transitional area 833, the splines 804 are tightly packed together because the surface segments have to be small in order to reproduce those curved surfaces of the foot well with acceptable accuracy.

Once the splines 804 have been assembled, the designer lofts an area between each pair of parallel splines 804 in order to create different areal segments 808. The “lofting” process proceeds along each of the major surfaces of the part, piecewise, until that surface is entirely recreated. For example, a transmission tunnel sidewall surface 810 is recreated by lofting an area 812 between a spline 814 to an adjacent spline 816 along the same surface. The designer then lofts the next area 818 from spline 816 to spline 820. Next, an area 822 from spline 820 to spline 824 is added, and so forth down the rest of the transmission tunnel surface 810 until that entire component of the vehicle foot well surface has been created. In similar fashion, the other major surfaces are added: a combination firewall/floor area segment 826, a pedestal sidewall 828, a kick plate segment 830, a sill plate curve 832 and the sill plate 806.

The resultant reconstructed vehicle foot well surface 802 is used, at steps 703-707, 709, 711, to construct a vehicle floor tray that fits the surface 802 to an enhanced degree of precision. At step 703, the designer chooses top and bottom sketch planes, which intersect the surface 802 at the top and bottom elevations of the tray to be designed. A top sketch plane intersects surface 802 at a locus high up on the sidewalls 810, 828, 830, 832 and 834. This locus is seen in FIG. 1 as a top margin 150 of the upstanding sidewalls 130, 132, 134, 136 and the transitions between them. In the preferred embodiment, the top sketch plane is tilted and inclines upward in a forward direction. This produces a tray which is deeper near the firewall than it is near the seat, preferably producing a tray that is at least five inches deep at its deepest part. This protects the foot well carpet from the possibly muddy sides of an occupant's shoes or boots. A bottom sketch plane is defined to be coplanar with the bottom surface tray sill plate 140, spaced from the vehicle foot well sill plate 806 by a tight tolerance, such as 0.025″. This bottom sketch plane does not intersect the remainder of the structure but is instead projected upward onto the vehicle foot well surface to create a locus that approximates the marginal outline of the floor/firewall segment 826.

At step 704, sidewalls are drawn in to span the top and bottom sketch planes. These prototypical sidewalls are created by first drawing a plurality of straight lines, each drawn from a point on the upper sketch plane locus to a point on the lower sketch plane locus. Since the upper sketch plane is more extensive and has a different shape from the lower sketch plane, the lateral margins of the upper and lower sketch planes are not congruent, and the straight lines drawn from the upper sketch plane may be canted at various angles to each other. In general, these lines will slope inwardly from the top sketch plane to the bottom sketch plane. The areas in between these lines can be lofted to create polygonal surfaces of a completed tray solid.

The resultant solid has a planar top surface, nearly planar bottom surface and sidewalls which make abrupt corners with them. The actual transitions between the vehicle foot well sidewall surfaces and the floor are almost always curved, to a greater or lesser extent depending on the area in question and on the vehicle model. Therefore, at step 705, curves are fitted to the reconstructed vehicle foot well surface and these curves are substituted in for the previous abrupt angular shapes. The largest of these curves occurs across the firewall 834, to conform to that sloping and typically curved surface rather than to a horizontal extension of the bottom sketch plane. Curves are also used to modify the transitions between the floor 102 and the transmission tunnel surface 132, the kick plate 136, and the seat pedestal sidewall 130.

The above techniques aim to approximate, as closely as possible, the shape of the upstanding sidewalls 810, 828, 830 and 834, to a zero standoff from the foot well surface. In some instances, the outer surface of the tray 100 may actually extend slightly beyond the imaged side walls of the vehicle foot well (see portions 1000-1006 in FIGS. 10-14), creating a negative standoff. This is permissible to some degree because the surface to which the tray is being shaped is carpeted and the pile may be intentionally depressed at certain points.

The door sill 806 and the sill curve 832 typically are hard surfaces that must comply to close manufacturer tolerances. A vehicle door is designed to mate with these surfaces. Because of this it is important to match these surfaces carefully, and preferably this is done in this process to a preselected standoff of 0.025 inch.

At step 704, and for certain vehicle models, certain radii of the transitional surfaces are increased, in an intentional departure from the foot well surface. This is done, for example, where the curved transition is one from a deep vertical surface to the floor, as might occur between a vertical kick plate and firewall surface segments 836, 838. See transition 1400 in FIG. 14. This is done to make sure that the preferred vacuum molding process, which uses a female tool, does not create a thin place in the molded part at the deep corners. Where the sidewall surfaces are sloped inward by more than five degrees, such radiusing is unnecessary.

At step 707, which can be before, during or after steps 704 and 705, the tray solid is additionally modified to take into account irregularities in the reconstructed foot well surface. For example, the vehicle carpeting might have had rolls or wrinkles in it that should not be reproduced in a tray meant to fit the vehicle. This steps also smooths out those surface irregularities which are artifacts of the surface acquisition and reconstruction steps 700-702.

Once a basic shape for the vehicle floor tray has been formed, it is modified at 709 in order to create the reservoir 110 and channels 104 (See FIGS. 1-4). This modification is necessary because, as has been explained, while there is a close conformance or mating between most of the exterior or lower surfaces of the floor tray on the one hand to the upper or interior surfaces of the vehicle foot well surfaces on the other, there must be a departure from this close conformance in order to create the profile needed by the reservoir and channels. In a preferred embodiment, a predetermined file containing the outer surface of the reservoir and channel surface is integrated into the floor of the tray solid. The importation of this design into the floor of the tray solid will cause a departure from the imaged vehicle surface floor of as much as ¼ inch in the areas around the reservoir periphery. This departure decreases as a function of distance from the imported pattern. The produced vehicle floor tray will nonetheless fit tightly to the vehicle foot well, because (1) the floor carpeting will be depressed to a greater extent under the reservoir than in peripheral areas (see, e.g., region 1004 in FIG. 10), and (2) the upstanding sidewalls continue to closely conform to the corresponding surfaces of the vehicle foot well.

At step 711, the tray solid developed at steps 703-707, 709 is “shelled”. This means that the solid is carved out to leave a thin layer that is a uniform thickness (preferably about 0.120-0.125 in.) from the outer surface.

The result is a tray data file 708 that is a complete representation of both the upper and lower surfaces of the floor tray, to a precision sufficient to create only a ⅛ in. departure or less from a large portion of the respective surfaces of the vehicle foot well. This data file, typically as translated into a .stl format that approximates surfaces with a large plurality of small triangles, is used at 710 to command a stereolithographic apparatus (SLA). The SLA creates a solid plastic image or model of the design by selectively curing liquid photopolymer using a laser. The SLA is used to determine fit to an actual vehicle foot well and to make any necessary adjustments.

As modified with experience gained from fitting the SLA, at 712 the vehicle tray data file is used to make a commercial mold for producing the vehicle floor trays or covers. Triextruded sheets or blanks 714 are placed in the mold and heated to produce the vehicle floor trays at 716.

Three-dimensional vehicle floor trays for many different vehicle models can be quickly and accurately manufactured using this method. The method can also be modified to produce double trays, in which a single tray is provided which covers both driver and passenger vehicle foot wells as well as the intervening transmission tunnel. The technique can be used to create other vehicle floor covers as well, such as the liners used in the cargo areas of minivans and SUVs.

In summary, a novel vehicle floor tray has been shown and described which fits, within tight tolerances, to the vehicle foot well for which it is created. The floor tray according to the invention includes a reservoir and channel system for retaining runoff in a way that will not slosh around in the foot well. By using a triextruded sheet blank, the tray combines the desirable coefficient of friction and yieldability characteristics of a thermoplastic elastomer, the lower cost of a polyolefin and a toughness that exceeds either material taken alone.

While an illustrated embodiment of the present invention has been described and illustrated in the appended drawings, the present invention is not limited thereto but only by the scope and spirit of the appended claims. 

1. A vehicle floor tray thermoformed from a sheet of thermoplastic polymeric material of substantially uniform thickness, comprising: a central panel substantially conforming to a floor of a vehicle foot well, the central panel of the floor tray having at least one longitudinally disposed lateral side and at least one transversely disposed lateral side; a first panel integrally formed with the central panel of the floor tray, upwardly extending from the transversely disposed lateral side of the central panel of the floor tray, and closely conforming to a first foot well wall, the first panel of the floor tray joined to the central panel of the floor tray by a curved transition; a second panel integrally formed with the central panel of the floor tray and the first panel, upwardly extending from the longitudinally disposed lateral side of the central panel of the floor tray, and closely conforming to a second foot well wall, the second panel of the floor tray joined to the central panel of the floor tray and to the first panel of the floor tray by curved transitions; a reservoir disposed in the central panel of the floor tray; a plurality of upstanding, hollow, elongate baffles disposed in the reservoir, each of the baffles having at least two ends remote from each other, the central panel, the first panel, the second panel, the reservoir and the baffles each having a thickness from a point on the upper surface to a closest point on the bottom surface thereof, said thicknesses, as a result of the tray being thermoformed from the sheet of thermoplastic polymeric material of substantially uniform thickness, being substantially uniform throughout the tray; the baffles each having a width more than two times the thickness of the last said substantially uniform thickness, the baffles adapted to elevate the shoe or foot of the occupant above fluid collected in the reservoir, the baffles each including at least one longitudinally oriented portion which impedes transverse movement, induced by vehicle acceleration, of fluid collected in the reservoir, and at least one transversely oriented portion joined to the at least one longitudinal portion and disposed to impede the longitudinal movement, induced by vehicle acceleration, of fluid collected in the reservoir, any portion of the reservoir connected to a remote portion of the reservoir by a path formed around ends of the baffles.
 2. The floor tray of claim 1, further comprising a third panel integrally formed with the central panel of the floor tray and joined to at least one of the first and second panels by curved transitions, the third panel upwardly extending from a third lateral side of the central panel of the floor tray.
 3. The floor tray of claim 2, further comprising a fourth panel integrally formed with the central panel of the floor tray and joined to at least one of the second and third panels by curved transitions, the fourth panel upwardly extending from a fourth lateral side of the central panel of the floor tray.
 4. The floor tray of claim 1, wherein at least one of the first and second panels has a top margin, the top margin being at least five inches higher than the central panel of the floor tray at its greatest vertical separation therefrom.
 5. The floor tray of claim 1, wherein the first and second panels have top margins which are substantially coplanar with each other. 